Problem Set 1 Solutions Due: see website for due date

Transcription

Problem Set 1 Solutions Due: see website for due date
Problem Set 1 Solutions
Due: see website for due date
Chapter 17: Wave Optics
Questions: 3, 7, 11, 15
Exercises & Problems: 4, 7, 8, 10, 24, 30, 44, 55, 67
Q17.3: The wavelength of a light wave is 700 nm in air; this light appears red. If this
wave enters a pool of water, its wavelength becomes λair/n = 530 nm. If you were
swimming underwater, the light would still appear red. Given this, what property of a
wave determines its color? Explain.
Solution
Q17.3. Reason: The wavelength changes (λn = λair / n) when the light goes from one medium to another, but the
frequency stays the same. Since the color doesn’t change, then it must be associated with the frequency.
Assess: Energy of the light is directly related to the frequency as well.
Q17.7: The figure shows the viewing screen in a double-slit
experiment with monochromatic light. Fringe C is the central
maximum.
a. What will happen to the fringe spacing if the wavelength of the
light is decreased?
b. What will happen to the fringe spacing if the spacing between the
slits is decreased?
c. What will happen to the fringe spacing if the distance to the screen is decreased?
d. Suppose the wavelength of the light is 500 nm. How much farther is it from the dot
on the screen in the center of fringe E to the left slit than it is from the dot to the right
slit?
Solution
Q17.7. Reason: The fringe separation for the light intensity pattern of a double slit is determined
λ L / d . We can answer this question by inspecting this relationship.
by ∆y =
(a) If λ decreases, ∆y will decrease.
(b) If d decreases, ∆y will increase.
(c) If L decreases, ∆y will decrease.
(d) Since the dot is in the m = 2 bright fringe, the path length difference from the two slits is 2λ = 1000 nm.
Assess: The ability to inspect a relationship and answer “what if ” questions is a skill that physics will help you
develop.
Q17.11: Why does light reflected from peacock feathers change color when you see the
feathers at a different angle? Explain.
Solution
Q17.11. Reason: Peacock feathers consist of thin nearly parallel rods of melanin. Since they are thin, thinfilm interference is a factor. Since they are very small and nearly parallel, they also act as a diffraction grating.
As a result different wavelengths add up constructively at different locations and you will see different colors
when viewing the feather from different angles.
Assess: This effect is common from biological structures whose size is similar to the wavelength of light.
Q17.15: Should the antireflection coating of a microscope objective lens designed for
use with ultraviolet light be thinner, thicker, or the same thickness as the coating on a
lens designed for visible light? Explain.
Solution
Q17.15. Reason: The wavelength of ultraviolet light is shorter than the wavelength of visible light. The
formulas for the thickness of thin films, such as those used as antireflection coatings, show the thickness is
proportional to the wavelength. Hence, if the wavelength is shorter, then the film needs to be thinner.
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Assess: It is difficult to make antireflection coatings that work at a wide range of wavelengths, but it can be
done somewhat with multiple layers of films of different indices of refraction.
P17.4: A light wave has a 670 nm wavelength in air. Its wavelength in a transparent solid
is 420 nm.
a. What is the speed of light in this solid?
b. What is the light’s frequency in the solid?
Solution
P17.4. Prepare: Light rays travel in straight lines and light’s speed in a material is characterized by its
refractive index, defined by Equation 17.1. Also, the frequency does not change as the wave moves from one
medium to another.
Solve: (a) The refractive index is
f λvac
c
λ
λ
420 nm
n=
=
= vac ⇒ vsolid = c solid = (3.0 × 108 m/s)
=1.88 × 108 m/s
vsolid
f λsolid λsolid
670 nm
λvac
or 1.9 × 108 m/s to two significant figures.
(b) The frequency is
vsolid 1.88 × 108 m/s
f
=
=
= 4.5 × 1014 Hz
420 nm
λsolid
Assess: We must not forget that the frequency of a wave does not change as the wave moves from one medium
into another.
P17.7: Two narrow slits 50 μm apart are illuminated with light of wavelength 500 nm.
What is the angle of the m = 2 bright fringe in radians? In degrees?
Solution
P17.7. Prepare: Two closely spaced slits produce a double-slit interference pattern given by Equation 17.6.
The interference pattern looks like the photograph of Figure 17.10. It is symmetrical with the m = 2 fringes on
both sides of and equally distant from the central maximum.
Solve: The bright fringes occur at angles θm such that
m = 0, 1, 2, 3, . . .
d sin θ m = mλ
2(500 × 10−9 m)
180 °
=
0.02
=
=
0.020 rad ×
1.1 °
−6
θ
=
0.020
rad
(50 × 10 m)
π rad
⇒ 2
Assess: We did expect the angle to be small because the wavelength of light is much smaller than the
separation of the two slits.
⇒
=
sin θ 2
P17.8: Light from a sodium lamp (λ = 589 nm) illuminates two narrow slits. The fringe
spacing on a screen 150 cm behind the slits is 4.0 mm. What is the spacing (in mm)
between the two slits?
Solution
P17.8. Prepare: Two closely spaced slits produce a double-slit interference pattern. The interference pattern
looks like the photograph of Figure 17.10.
Solve: The fringe spacing is given by Equation 17.9 as follows:
λL
λ L (589 × 10−9 m)(150 × 10−2 m)
∆y=
⇒ d=
=
= 0.22 mm
d
∆y
4.0 × 10−3 m
P17.10: A double-slit experiment is performed with light of wavelength 600 nm. The bright
interference fringes are spaced 1.8 mm apart on the viewing screen. What will the fringe
spacing be if the light is changed to a wavelength of 400 nm?
Solution
P17.10. Prepare: Two closely spaced slits produce a double-slit interference pattern. The interference pattern
looks like the photograph of Figure 17.10.
Solve: The formula for fringe spacing is Equation 17.9.
λL
L
L
∆y=
⇒ 1.8 × 10−3 m =(600 × 10−9 m)
= 3000
d
d ⇒ d
The wavelength is now changed to 400 nm, and L / d , being a part of the experimental setup, stays the same.
Applying the above equation once again,
2
∆y=
λL
d
= (400 × 10−9 m)(3000)= 1.2 mm
P17.24: Antireflection coatings can be used on the inner surfaces of eyeglasses to
reduce the reflection of stray light into the eye, thus reducing eyestrain.
a. A 90-nm-thick coating is applied to the lens. What must be the coating’s index of
refraction to be most effective at 480 nm? Assume that the coating’s index of
refraction is less than that of the lens.
b. If the index of refracting of the coating is 1.38, what thickness should the coating be
so as to be most effective at 480 nm? The thinnest possible coating is best.
Solution
P17.24. Prepare: First note that the coating is on the inside of the glass. As the incident light reflects off the
air-coating interface there is no phase change. As the light that is transmitted through the coating reflects off the
coating-air interface there is no phase change. Destructive interference for two reflective no-phase changes
occurs when 2=
t (m + 1/2)λair / n.
We will use m = 1 in order to obtain the thinnest possible coating.
Solve: (a) The index of refraction for the coating is n =
(m + 1/2)λair /(2t ) ==
λair /(4t ) 480 nm/(4(90 nm)) =
1.33.
(b) The thickness of the coating is
1

t=
(480 nm)/4(1.38) =
87 nm
λ /4n =
 m + 2  λair /2n =


Assess: This is a reasonable value for the index of refraction thickness of the coating (see Problem 17.26).
P17.30: A 0.50-mm-wide slit is illuminated by light of wavelength 500 nm. What is the
width of the central maximum on a screen 2.0 m behind the slit?
Solution
P17.30. Prepare: A narrow slit produces a single-slit diffraction pattern. The intensity pattern for single-slit
diffraction will look like Figure 17.27 with minima given by Equation 17.20. The width of the central maximum
is given by Equation 17.21.
Solve: The width of the central maximum for a slit of width a = 200λ is
2λ L 2(500 × 10−9 m)(2.0 m)
w =
=
= 0.0040=
m
4.0 mm
a
0.0005 m
P17.44: The two most prominent wavelengths in the light emitted by a hydrogen
discharge lamp are 656 nm (red) and 486 nm (blue). Light from a hydrogen lamp
illuminates a diffraction grating with 500 lines/mm, and the light is observed on a screen
1.50 m behind the grating. What is the distance between the first-order red and blue
fringes?
Solution
P17.44. Prepare: A diffraction grating produces an interference pattern. The interference pattern looks like the
diagram of Figure 17.12. The bright interference fringes are given by Equation 17.12 d sin θ m = mλ , m = 0, 1, 2, 3, . . .
The slit spacing is=
= 2.00 × 10−6 m and m = 1.
d 1 mm/500
Solve: For the red and blue light,
 656 × 10−9 m 
=
 19.15 °
−6
 2.00 × 10 m 
sin −1 
θ=
1 red
 486 × 10−9 m 
=
 14.06 °
−6
 2.00 × 10 m 
sin −1 
θ=
1 blue
The distance between the fringes, then, is ∆=
y y1 red − y1 blue where
=
y1 red (1.5=
m) tan1 9.15 ° 0.521 m
=
y1 blue (1.5=
m) tan1 4.06 ° 0.376 m
=
∆y 0.145
=
m 14.5 cm.
So,
P17.55: If sunlight shines straight onto a peacock feather, the feather appears bright
blue when viewed from 15° on either side of the incident beam of sunlight. The blue
color is due to diffraction from the from the melanin bands in the feather barbules. Blue
light with a wavelength of 470 nm is diffracted at 15° by these bands (this is the first3
order diffraction) while other wavelengths in the sunlight are diffracted at different
angles. What is the spacing of the melanin bands in the feather?
Solution
P17.55. Prepare: The peacock feather is acting as a reflection grating, so we may use Equation 17.12:
d sin θ m = mλ , with m = 1 (we are told it is first-order diffraction), λ = 470 nm, and θ1 = 15 ° = 0 . 262 rad.
Solve: Solve Equation 17.12 for d .
mλ
(1)(470 × 10−9 m)
d=
=
= 1.8 µ m
sin θ m
sin(0 . 262 rad)
Assess: The answer is small, but plausible for the bands on the barbules.
P17.67: The figure shows the light intensity on a screen behind a single slit. The
wavelength of the light is 500 nm and the screen is 1.0 m behind the slit. What is the
width (in mm) of the slit?
Solution
P17.67. Prepare: Please refer to Figure P17.67. A narrow slit produces a single-slit diffraction pattern. The
diffraction-intensity pattern from a single slit will look like Figure 17.27. As given by Equation 17.20, the dark fringes in
this diffraction pattern: y p = pλ L / a, p = 1, 2, 3, . . .
Solve: We note from Figure P17.67 that the first minimum is 0.50 cm away from the central maximum. Using
the above equation, the slit width is
pλ L (1)(500 × 10−9 m)(1.0 m)
a =
=
= 0.10 mm
0.50 × 10−2 m
yp
Assess: This is a typical slit width for diffraction.
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